Your search keyword '"Lindackers, D."' showing total 4 results

1. An ultra-high vacuum scanning tunneling microscope operating at sub-Kelvin temperatures and high magnetic fields for spin-resolved measurements.

Author

Salazar, C., Baumann, D., Hänke, T., Scheffler, M., Kühne, T., Kaiser, M., Voigtländer, R., Lindackers, D., Büchner, B., and Hess, C.

Subjects

SCANNING tunneling microscopy, KELVIN temperature scale, CRYOGENICS, THIN film deposition, SUPERCONDUCTORS

Abstract

We present the construction and performance of an ultra-low-temperature scanning tunneling microscope (STM), working in ultra-high vacuum (UHV) conditions and in high magnetic fields up to 9 T. The cryogenic environment of the STM is generated by a single-shot 3He magnet cryostat in combination with a 4He dewar system. At a base temperature (300 mK), the cryostat has an operation time of approximately 80 h. The special design of the microscope allows the transfer of the STM head from the cryostat to a UHV chamber system, where samples and STM tips can be easily exchanged. The UHV chambers are equipped with specific surface science treatment tools for the functionalization of samples and tips, including high-temperature treatments and thin film deposition. This, in particular, enables spin-resolved tunneling measurements. We present test measurements using well-known samples and tips based on superconductors and metallic materials such as LiFeAs, Nb, Fe, and W. The measurements demonstrate the outstanding performance of the STM with high spatial and energy resolution as well as the spin-resolved capability. [ABSTRACT FROM AUTHOR]

Published

2018

2. Design and properties of a cryogenic dip-stick scanning tunneling microscope with capacitive coarse approach control.

Author

Schlegel, R., Hänke, T., Baumann, D., Kaiser, M., Nag, P. K., Voigtländer, R., Lindackers, D., Büchner, B., and Hess, C.

Subjects

SCANNING tunneling microscopy, CRYOSTATS, SUPERCONDUCTORS, MAGNETIC fields, SPECTRUM analysis

Abstract

We present the design, setup, and operation of a new dip-stick scanning tunneling microscope. Its special design allows measurements in the temperature range from 4.7 K up to room temperature, where cryogenic vacuum conditions are maintained during the measurement. The system fits into every 4He vessel with a bore of 50 mm, e.g., a transport dewar or a magnet bath cryostat. The microscope is equipped with a cleaving mechanism for cleaving single crystals in the whole temperature range and under cryogenic vacuum conditions. For the tip approach, a capacitive automated coarse approach is implemented. We present test measurements on the charge density wave system 2H-NbSe2 and the superconductor LiFeAs which demonstrate scanning tunneling microscopy and spectroscopy data acquisition with high stability, high spatial resolution at variable temperatures and in high magnetic fields. [ABSTRACT FROM AUTHOR]

Published

2014

3. Selective laser melting of La(Fe,Co,Si)13 geometries for magnetic refrigeration.

Author

Moore, J. D., Klemm, D., Lindackers, D., Grasemann, S., Träger, R., Eckert, J., Löber, L., Scudino, S., Katter, M., Barcza, A., Skokov, K. P., and Gutfleisch, O.

Subjects

MAGNETIC cooling, MELTING, LASER research, LANTHANUM, MAGNETOCALORIC effects

Abstract

Magnetic cooling prototypes based on the magnetocaloric effect require the magnetic refrigerant to be shaped into geometries that enable quick and efficient heat-transfer to the transfer fluid. Simple solutions include a stack of parallel-plates or a bed of packed-spheres. Here, we demonstrate how more sophisticated geometries can be made by using selective laser melting, a rapid prototyping technique to form three-dimensional shapes. Using excellent magnetocaloric La(Fe,Co,Si)13 as starting-powder we made two geometries: a wavy-channel block with a high surface-to-volume ratio and an array of fin-shaped rods which eliminate unwanted heat conduction along the magnetic part. After annealing treatment, the geometries are intact and can survive more than 106 cycles of applying a magnetic field while still maintaining good magnetocaloric properties. This fabrication approach shows promise for making near-net shaped magnetic refrigerants with superior heat transfer properties and performance. [ABSTRACT FROM AUTHOR]

Published

2013

4. Fast-current-heating devices to study in situ phase formation in metallic glasses by using high-energy synchrotron radiation.

Author

Orava J, Kosiba K, Han X, Soldatov I, Gutowski O, Ivashko O, Dippel AC, Zimmermann MV, Rothkirch A, Bednarcik J, Kühn U, Siegel H, Ziller S, Horst A, Peukert K, Voigtländer R, Lindackers D, and Kaban I

Abstract

Details of fast-resistive-heating setups, controlled heating ranging from ∼10 1 K s -1 to ∼10 3 K s -1 , to study in situ phase transformations (on heating and on cooling) in metallic glasses by high-energy synchrotron x-ray diffraction are discussed. Both setups were designed and custom built at the Leibniz Institute for Solid State and Materials Research Dresden (IFW Dresden) and have been implemented at the P02.1 Powder Diffraction and Total Scattering Beamline and the P21.1 Swedish Materials Science Beamline at PETRA III storage ring, DESY, Hamburg. The devices are interchangeable at both beamlines. Joule heating is triggered automatically and is timed with the incident beam and detector. The crystallization process can be controlled via a feedback circuit by monitoring the change in the time-dependent resistivity and temperature of glasses. Different ambient atmospheres, such as vacuum and inert gases (He and Ar), can be used to control oxidation and cooling. The main focus of these devices is on understanding the crystallization mechanism and kinetics in metallic glasses, which are brittle and for which fast heating gives defined glass-crystal composites with enhanced plasticity. As an example, phase-transformation sequence(s) in a prototyped Cu-Zr-based metallic glass is described on heating, and a crystalline phase beneficial to the plasticity is identified.

Published

2020